Topography of somatosensory processing: Cerebral lateralization and focused attention

K.J. MEADOR; J.D. ALLISON; D.W. LORING; T.B. LAVIN; J.J. PILLAI

doi:10.1017/S1355617702813169

Abstract

Healthy dextrals underwent fMRI during a task of graphesthesia requiring detection of any number written consecutively from an otherwise random number sequence. Test conditions included (1) focus on unilateral right hand stimuli, (2) focus on unilateral left hand stimuli, (3) focus on right hand only during bilateral hand stimulation, (4) focus on left hand only during bilateral hand stimulation, and (5) rest. Attention to unilateral hand stimulation produced bihemispheric activation with minimal or no activation of ipsilateral primary sensorimotor region. Attention to unilateral left hand stimuli resulted in more activation than attention to unilateral right hand stimuli. Stimulation of the nonattended hand activated the contralateral somatosensory area, but to a lesser spatial extent than attended stimuli. Comparing focused attention to the left versus right side during identical sensory inputs (i.e., bilateral hand stimulation), focused attention to the right hand increased activation in the left somatosensory region, but focused attention to the left hand increased activation in both cerebral hemispheres. Thus, focused attention to unilateral somatosensory stimuli produces bilateral cerebral activation, but the increase in blood flow is greater in the contralateral hemisphere. Unattended stimuli activate the contralateral primary somatosensory area. Left/right asymmetries were demonstrated consistent with cerebral lateralization. (JINS, 2002, 8, 349–359.)

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Loring, D.W Meador, K.J Allison, J.D Pillai, J.J Lavin, T Lee, G.P Balan, A and Dave, V 2002. Now you see it, now you don’t: statistical and methodological considerations in fMRI. Epilepsy & Behavior, Vol. 3, Issue. 6, p. 539.

Fang, SY Wang, JJ Hsu, YY Wan, YL Wai, YY and Liu, HL 2006. Effects of single-trial averaging on spatial extent of brain activation detected by fMRI are subject and task dependent. Biomedical Imaging and Intervention Journal, Vol. 2, Issue. 3,

Duncan, R. O. and Boynton, G. M. 2007. Tactile Hyperacuity Thresholds Correlate with Finger Maps in Primary Somatosensory Cortex (S1). Cerebral Cortex, Vol. 17, Issue. 12, p. 2878.

Burton, Harold Sinclair, Robert J. and McLaren, Donald G. 2008. Cortical network for vibrotactile attention: A fMRI study. Human Brain Mapping, Vol. 29, Issue. 2, p. 207.

Schubert, Ruth Ritter, Petra Wüstenberg, Torsten Preuschhof, Claudia Curio, Gabriel Sommer, Werner and Villringer, Arno 2008. Spatial Attention Related SEP Amplitude Modulations Covary with BOLD Signal in S1—A Simultaneous EEG—fMRI Study. Cerebral Cortex, Vol. 18, Issue. 11, p. 2686.

Gregory, Stanford W. Kalkhoff, Will Harkness, Sarah K. and Paull, Jessica L. 2009. Targeted high and low speech frequency bands to right and left ears respectively improve task performance and perceived sociability in dyadic conversations. Laterality: Asymmetries of Body, Brain and Cognition, Vol. 14, Issue. 4, p. 423.

Anderson, K.L. and Ding, M. 2011. Attentional modulation of the somatosensory mu rhythm. Neuroscience, Vol. 180, Issue. , p. 165.

Eek, Elsy Holmqvist, Lotta Widén and Sommerfeld, Disa K. 2012. Adult norms of the perceptual threshold of touch (PTT) in the hands and feet in relation to age, gender, and right and left side using transcutaneous electrical nerve stimulation. Physiotherapy Theory and Practice, Vol. 28, Issue. 5, p. 373.

Goltz, Dominique Pleger, Burkhard Thiel, Sabrina Villringer, Arno Müller, Matthias M. and Antal, Andrea 2013. Sustained Spatial Attention to Vibrotactile Stimulation in the Flutter Range: Relevant Brain Regions and Their Interaction. PLoS ONE, Vol. 8, Issue. 12, p. e84196.

Popovich, Christina and Staines, W. Richard 2014. The attentional‐relevance and temporal dynamics of visual‐tactile crossmodal interactions differentially influence early stages of somatosensory processing. Brain and Behavior, Vol. 4, Issue. 2, p. 247.

Brown, Matt J. N. and Staines, W. Richard 2015. Modulatory effects of movement sequence preparation and covert spatial attention on early somatosensory input to non-primary motor areas. Experimental Brain Research, Vol. 233, Issue. 2, p. 503.

Li Hegner, Yiwen Lindner, Axel and Braun, Christoph 2015. Cortical correlates of perceptual decision making during tactile spatial pattern discrimination. Human Brain Mapping, Vol. 36, Issue. 9, p. 3339.

Meador, Kimford J. Revill, Kathleen Pirog Epstein, Charles M. Sathian, K. Loring, David W. and Rorden, Chris 2017. Neuroimaging somatosensory perception and masking. Neuropsychologia, Vol. 94, Issue. , p. 44.

Goodin, Peter Lamp, Gemma Vidyasagar, Rishma McArdle, David Seitz, Rüdiger J. and Carey, Leeanne M. 2018. Altered functional connectivity differs in stroke survivors with impaired touch sensation following left and right hemisphere lesions. NeuroImage: Clinical, Vol. 18, Issue. , p. 342.

Article contents

Topography of somatosensory processing: Cerebral lateralization and focused attention

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Topography of somatosensory processing: Cerebral lateralization and focused attention

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests